JP5474718B2 - Leakage current measuring device - Google Patents

Description

  The present invention relates to a leakage current measuring apparatus that measures a leakage current such as a patient measurement current for a device to be measured (electrical device) based on a safety standard such as IEC 60601-1.

  In this type of leakage current measuring device, a simulation circuit that switches the polarity of the commercial AC voltage supplied to the device under measurement is described, for example, on page 6 of Non-Patent Document 1 below. is necessary. As an example of the simulation circuit, a simulation circuit 60 shown in FIG. 3 is described in the IEC 60601-1 standard. The simulation circuit 60 includes an insulation transformer 41, a polarity changeover switch 61, and a connection / disconnection switch 62. Insulation transformer 41 has primary winding 41a connected to a pair of AC input terminals 2a and 2b to which commercial AC voltage V1 is input, and outputs insulated commercial AC voltage V1 from secondary winding 41b. The polarity changeover switch 61 is configured by a two-pole double-throw switch (toggle switch, slide switch, etc.) as an example. Further, the polarity changeover switch 61 has each pole connected in a connection state shown in FIG. 3 to supply electric circuits 24 and 25 that connect each end of the secondary winding 41b and the pair of AC output terminals 3a and 3b, respectively. Yes. The connection / disconnection switch 62 is a single-pole / single-throw switch. Further, the connection / disconnection switch 62 is connected to the supply electric circuit 25 on the grounded side of the supply electric circuits 24 and 25, and connects / disconnects (connects or disconnects) the supply electric circuit 25. Note that PE in FIG. 3 indicates protective grounding in the device under measurement 50, FE indicates functional grounding in the device under measurement 50, and each of the PE and FE is individually grounded to the simulation circuit 60. The two switches 29 and 30 are provided.

  Therefore, in the leakage current measuring device 65 provided with the AC input terminals 2a and 2b, the AC output terminals 3a and 3b, and the simulation circuit 60, the polarity changeover switch 61 of the simulation circuit 60 is operated, so The polarity of the commercial AC voltage V1 supplied to the ground can be switched, and by operating the connection / disconnection switch 62, it is possible to connect / disconnect the supply circuit 25 on the ground side. Each state before and after switching when the polarity of the commercial AC voltage V1 is switched with the power supply circuit 25 connected, and switching when the polarity of the commercial AC voltage V1 is switched with the supply circuit 25 on the ground side disconnected In each state before and after, a current flowing through a measurement network (not shown) connected according to the standard can be measured as a leakage current.

  However, the following problems exist in the leakage current measuring device 65 including the simulation circuit 60 described above. That is, in this simulation circuit 60, every time the polarity changeover switch 61 is operated to switch the polarity of the commercial AC voltage V1 supplied to the device under measurement 50, the commercial AC voltage V1 to the device under measurement 50 is switched. Is temporarily interrupted. For this reason, when the measurement target device 50 includes a personal computer, it is necessary to avoid destruction of data being processed in the personal computer. Therefore, when switching the polarity of the commercial AC voltage V1, first, the personal computer of the device under measurement 50 is shut down, then the polarity switch 61 is operated to switch the polarity of the commercial AC voltage V1, An operation of restarting (restarting) the personal computer of the device under measurement 50 is always necessary. Therefore, there is a problem that it takes a long time to measure the leakage current of the device under measurement 50 including the personal computer.

  In order to solve this problem, the present inventor has already developed and proposed the following leakage current measuring device (Japanese Patent Application No. 2010-133516). This leakage current measuring device includes a simulation circuit including a polarity switching circuit that switches the polarity of an input commercial AC voltage and supplies it to a device under measurement, and a measurement network that constitutes a leakage current path for the device under measurement. A leakage current measuring device having a voltmeter for measuring a voltage between both ends, wherein a polarity switching circuit is connected to both ends of a secondary winding of an insulating transformer in which a commercial AC voltage is input to the primary winding. A pair of supply electric circuits that supply the commercial AC voltage output from the secondary winding and supply it to the device to be measured, and a ground switch that selectively grounds one of the pair of supply electric circuits. I have.

  Unlike the conventional configuration in which the polarity of the commercial AC voltage is switched using a two-pole double-throw switch, this leakage current measuring device continuously operates the commercial AC voltage to each AC output terminal by operating the ground switch. The polarity of this commercial AC voltage can be switched while outputting the signal. For this reason, even if the device under measurement includes a personal computer, it is possible to measure the leakage current of the device under measurement without shutting down or restarting the personal computer.

  Further, in this leakage current measuring device, a current limiting resistor connected in series to the ground switch, a short-circuit switch connected in parallel to the current limiting resistor and configured to be able to short-circuit the current limiting resistor, Since it has an ammeter that detects the current flowing through the limiting resistor, an isolation transformer is separately prepared, the commercial AC voltage V1 is supplied to the primary winding, and the commercial AC voltage V1 output from the secondary winding In the configuration in which is supplied to the pair of power supply circuits 24 and 25 of the simulation circuit 60, it is possible to determine whether or not the insulation transformer is connected (used) based on the current detected by the ammeter.

  Specifically, when the insulating transformer is connected, the secondary winding side of the insulating transformer is in a floating state with respect to the ground. For this reason, even if the secondary winding side is grounded, the current value of the current flowing between the secondary winding and the ground is extremely small. As a result, a current value slightly larger than this small current value is defined as a threshold value, and the current value of the current detected by the ammeter is compared with this threshold value. Therefore, it can be determined that the insulation transformer is connected. Therefore, according to this leakage current measuring apparatus, only when it is determined that the insulation transformer is normally connected, the short-circuit switch is operated and any one of the pair of supply electric circuits is grounded via the ground switch. Therefore, it is possible to avoid a situation where one of the pair of power supply paths is grounded (short-circuited) via a ground switch in a state where a commercial AC voltage is directly input without passing through an insulating transformer. It is possible.

HIOKI, 3156 Leak Current HiTester, User's Guide, [Search September 9, 2010], Internet <URL: http://hioki.jp/tech/pdf/3156UGJ_02.pdf>

  However, in the neutral wire that constitutes the commercial AC line together with the live electric wire, the voltage generated in the neutral wire with respect to the ground may be as low as several volts to several tens of volts. Even when the insulation transformer is not connected, when the neutral wire side is short-circuited via the current limiting resistor, the current flowing through the current limiting resistor may be less than the threshold value. For this reason, in such a case, the above leakage current measuring apparatus misclassifies that an insulating transformer is connected, and based on this determination result, in order to switch the polarity of the commercial AC voltage with respect to the device under measurement, When a live wire is short-circuited, a current exceeding the operating current (sensitivity current) of the earth leakage breaker flows between the commercial AC line and ground, and as a result, the earth leakage breaker installed in the commercial AC line is activated. Thus, there is a problem to be solved that the supply of commercial AC voltage to the device to be measured may be interrupted (shut off).

  The present invention has been made in view of such problems, and can reliably determine the connection of the insulation transformer and switch the polarity of the commercial AC voltage without interrupting the supply of the commercial AC voltage to the device under measurement. The main object is to provide a leakage current measuring device.

  In order to achieve the above object, the leakage current measuring apparatus according to claim 1 is a circuit that includes a polarity switching circuit that switches the polarity of an input commercial AC voltage and supplies the commercial AC voltage to the device under measurement, and the device under measurement. A voltmeter for measuring the voltage across the measurement network constituting the leakage current path and a processing unit, and the polarity switching circuit includes a secondary of an isolation transformer in which the commercial AC voltage is input to a primary winding. A pair of power supply lines connected to both ends of the winding, and supplied to the device under measurement by inputting the insulated commercial AC voltage output from the secondary winding; a current limiting resistor; A grounding switch that is connected in series with the current limiting resistor and selectively grounds any one of the pair of power supply paths via the current limiting resistor, and is connected in parallel with the current limiting resistor. Tote A short-circuit switch configured to be capable of short-circuiting a current limiting resistor; and an ammeter that detects a current flowing through the ground switch; and the processing unit is connected to the ground switch when the short-circuit switch is in a disconnected state. By executing the control, the pair of supply electric circuits are grounded one by one through the current limiting resistor and the current value of the current when grounded is measured by the ammeter, and any of the measured current values is measured Is determined to be connected to the polarity switching circuit when the threshold value is equal to or less than a predetermined threshold value, and when at least one of the measured current values exceeds the threshold value, Transformer connection detection processing is performed to determine that the insulating transformer is not connected to the polarity switching circuit.

  The leakage current measuring device according to claim 2 is the leakage current measuring device according to claim 1, wherein when the processing unit determines that the insulating transformer is not connected in the transformer connection detection processing, The effect is output to the output unit.

  In the leakage current measuring apparatus according to claim 1, prior to execution of the leakage current measurement process, the processing unit performs control on the ground switch, thereby grounding the pair of supply circuits one by one through the current limiting resistor. Measure each current value of the current that flows through the current limiting resistor when grounded together with an ammeter, and connect the insulation transformer to the polarity switching circuit when any measured current value is less than a predetermined threshold value. When at least one of the measured current values exceeds the threshold value, a transformer connection detection process is performed to determine that the insulating transformer is not connected to the polarity switching circuit.

  Therefore, according to this leakage current measuring apparatus, it is possible to reliably determine whether or not the insulating transformer is connected to the polarity switching circuit by the transformer connection detection process. The leakage current measurement process performed while switching the power supply can be executed while reliably avoiding the interruption of the commercial AC line by the earth leakage breaker (interruption of the supply of the commercial AC voltage).

  According to the leakage current measuring apparatus of claim 2, when the processing unit determines that the insulating transformer is not connected to the polarity switching circuit in the transformer connection detection processing, the fact is output to the output unit. Thus, the operator can surely and easily grasp that the insulating transformer is not connected.

1 is a configuration diagram showing a configuration of a leakage current measuring device 1. FIG. It is a block diagram which shows the structure of 1 A of leakage current measuring devices. It is a block diagram which shows the structure of the conventional leakage current measuring apparatus 65. FIG.

  Hereinafter, embodiments of the leakage current measuring apparatus 1 will be described with reference to the accompanying drawings.

  First, the configuration of the leakage current measuring apparatus 1 will be described with reference to the drawings.

  1 includes an inlet 2, an outlet 3, a simulation circuit 4, a measurement network 5, a voltmeter 6, test terminals 7a and 7b, test leads 8a and 8b, a processing unit 9, The operation unit 10 and the output unit 11 are provided, and as an example, a patient measurement current I1 as a leakage current defined in IEC 60601-1 can be measured for the device under measurement 50.

  As shown in FIG. 1, the inlet 2 is provided with a pair of AC input terminals 2a and 2b and a ground terminal 2c. Each pair of AC input terminals 2a and 2b is connected to each end of a secondary winding 41b in an insulation transformer 41 (external insulation transformer) prepared separately. The insulation transformer 41 includes a primary winding 41a and a secondary winding 41b (which is defined to have the same number of turns) that is electrically insulated from the primary winding 41a. The commercial AC voltage V1 input to the line 41a is converted into a commercial AC voltage V1 that is electrically insulated from the primary side and output from the secondary winding 41b. In addition, a pair of power supply circuits (power lines) 24 and 25 described later are connected to the pair of AC input terminals 2a and 2b. The ground terminal 2c is connected to an internal ground G1 that is a reference potential in the leakage current measuring apparatus 1. The outlet 3 is provided with a pair of AC output terminals 3a and 3b and a ground terminal 3c.

  As shown in FIG. 1, the simulation circuit 4 includes a ground switch 21, two connection switches 22 and 23, a pair of power supply paths 24 and 25, a current limiting resistor 26, and a short-circuit switch connected in parallel to the current limiting resistor 26. 27, an ammeter 28, and two connection switches 29, 30. The ground switch 21 is configured by a single-pole double-throw switch (in this example, a single-pole double-throw relay), and is supplied in a state of being connected in series with a current limiting resistor 26 and an ammeter 28. It arrange | positions between the electric circuits 24 and 25 and the internal ground G1. The ground switch 21 is connected to any one of the supply electric circuits 24 and 25 (of the two ends of the secondary winding 41b connected to the supply electric circuits 24 and 25 via the AC input terminals 2a and 2b). Any one of them) can be selectively connected to the internal ground G1 via the parallel circuit of the current limiting resistor 26 and the short-circuit switch 27 and the ammeter 28.

  The current limiting resistor 26 is a commercial power line (neutral line and neutral line) when the short-circuit switch 27 is in a disconnected state (a state in which the short-circuit switch 27 is not short-circuited) and the pair of power supply paths 24 and 25 are not connected to the insulation transformer 41. In a state where the live wire is directly connected, when this live wire is connected to the internal ground G1 via the ground switch 21, the current flowing in itself (current limiting resistor 26) is arranged in the commercial power line. The resistance value is set in advance so as to be lower than the operating current (for example, about 12 mA) of the earth leakage breaker (for example, the resistance value is set so that the current flowing through itself is about 10 mA).

  The short-circuit switch 27 is composed of a single-pole single-throw switch (in this example, a single-pole single-throw relay), and is connected in parallel to the current limiting resistor 26. With this configuration, the short-circuit switch 27 shorts the current limiting resistor 26 when in the connected state (ON state). The ammeter 28 is connected in series to the parallel circuit of the current limiting resistor 26 and the short-circuit switch 27 and the ground switch 21, so that the current flowing through the ground switch 21 (the current flowing through the current limiting resistor 26 or the short-circuit switch 27). ) Measure the current value of I3. Further, the ammeter 28 outputs current data Di indicating the measured current value of the current I3 to the processing unit 9.

  The secondary winding 41b of the isolation transformer 41 connected to the AC input terminals 2a and 2b is in a floating state without the ground switch 21, the current limiting resistor 26, the short-circuit switch 27, and the ammeter 28. For this reason, in a state where the current limiting resistor 26 is short-circuited by the short-circuit switch 27, the secondary winding 41b is not connected to the secondary winding 41b until one of the power supply circuits 24 and 25 is connected to the internal ground G1 by the ground switch 21. The polarity of the generated AC voltage is defined. That is, the supply circuit connected to the internal ground G1 through the ground switch 21 of the supply circuits 24 and 25 is defined as a neutral line, and the other supply circuit is defined as a polarity that becomes a live wire. Therefore, the polarity switching circuit 31 that switches the polarity of the commercial AC voltage V1 input to the AC input terminals 2a and 2b and supplies (outputs) the commercial AC voltage V1 to the outlet 3 includes the supply electric circuits 24 and 25, the ground switch 21, the ammeter 28, the current A limiting resistor 26 and a short-circuit switch 27 are included.

  The connection / disconnection switch 22 is configured by a single-pole single-throw switch (in this example, a single-pole single-throw relay) as an example, and the supply circuit 24 (the AC input terminal 2a and the AC output terminal 3a) is connected. Connected to the electrical circuit). Thereby, the connection / disconnection switch 22 can connect / disconnect (connect or disconnect) the power supply circuit 24, that is, can connect / disconnect between the AC input terminal 2a and the AC output terminal 3a (one AC output terminal). It has become. The disconnect switch 23 is composed of a single-pole single-throw switch (in this example, a single-pole single-throw relay) in the same manner as the disconnect switch 22, and is connected to the supply circuit 25 (the AC input terminal 2b). Connected to the AC output terminal 3b). Thereby, the connection / disconnection switch 23 can connect / disconnect (connect or disconnect) the supply electric circuit 25, that is, can connect / disconnect between the AC input terminal 2b and the AC output terminal 3b (the other AC output terminal). It has become.

  Further, the simulation circuit 4 includes two connection switches 29 for individually grounding the protective ground PE and the internal ground G1 in the device under measurement 50 and the functional ground FE and the internal ground G1 in the device under measurement 50, 30 is provided. The connection switch 29 is connected to the protective ground PE via the ground terminal 3 c of the outlet 3. Each of the connection switches 29 and 30 is constituted by a single pole single throw type switch (in this example, a single pole single throw type relay) as an example.

  The measurement network 5 is composed of a known resistance network. The measurement network 5 is connected between the test terminals 7a and 7b as shown in FIG. A test lead 8a is connected to the test terminal 7a, and a test lead 8b is connected to the test terminal 7b. As a result, the patient measurement current I1 can flow to the measurement network 5 via the test leads 8a and 8b. The voltmeter 6 measures a voltage value of a voltage generated between predetermined portions in the measurement network 5 (for example, between both ends of the measurement network 5) when the patient measurement current I1 flows. In addition, the voltmeter 6 outputs voltage data Dv indicating the voltage value of the measured voltage to the processing unit 9. As described above, since the measurement network 5 is composed of a known resistance network, the resistance value between the parts where the voltage is measured by the voltmeter 6 is also known. Therefore, the patient measurement current I1 can be measured based on the known resistance value and the voltage value of the voltage measured by the voltmeter 6.

  The processing unit 9 includes a CPU 9a and a memory 9b, and controls the ground switch 21, the connection switches 22, 23, the short-circuit switch 27, and the connection switches 29, 30 based on the switching instruction output from the operation unit 10. Processing, transformer connection detection processing for detecting whether or not the insulation transformer 41 is connected based on the current data Di, measurement processing of the patient measurement current I1 (leakage current measurement processing) based on the voltage data Dv, and output processing are executed. Further, in the transformer connection detection process, the processing unit 9 executes a control process for controlling the ground switch 21 and connecting the supply electric paths 24 and 25 to the ammeter 28 one by one. The memory 9b of the processing unit 9 preliminarily stores a threshold value (threshold value for each current value I3a, I3b described later) Ith used in the transformer connection detection process.

  For example, the operation unit 10 includes operation switches corresponding to the ground switch 21, the connection switches 22 and 23, the short-circuit switch 27, and the connection switches 29 and 30 in the simulation circuit 4, and corresponds to the operated operation switch. For each switch 21, 22, 23, 27, 29, 30 in the simulation circuit 4, a switching instruction corresponding to the operation content is generated and output to the processing unit 9. The output unit 11 includes a display device such as an LCD (Liquid Crystal Display) as an example, and displays the result of the transformer connection detection process by the processing unit 9 and the result of the measurement process. Note that the output unit 11 may be configured by an LED (Light Emitting Diode) or the like instead of the LCD.

  Next, the procedure for measuring the patient measurement current I1 for the device under measurement 50 using the leakage current measuring apparatus 1 will be described together with the measurement operation of the leakage current measuring apparatus 1.

  As a pre-measurement step, an insulating transformer 41 is prepared, and the secondary winding 41b is connected between the AC input terminals 2a and 2b. In addition, the power cable PW of the device under measurement 50 is connected to the outlet 3 of the leakage current measuring device 1, and the test lead 8 a of the leakage current measuring device 1 is connected to one mounting portion 51 of the device under measurement 50. Then, the test lead 8 b is connected to the other mounting part 52 of the device under measurement 50. Further, the ground terminal 2 c of the inlet 2 is connected to the external ground G.

  In this state, first, as an initial setting for the leakage current measuring apparatus 1, an operation switch corresponding to the ground switch 21 or the like in the operation unit 10 is operated to cause the processing unit 9 to execute a control process for the ground switch 21 or the like. As a result, the ground switch 21 is switched to the supply electric circuit 25 side, the connection / disconnection switches 22 and 23 are shifted to the connected state (ON state), and the short-circuit switch 27 is shifted to the disconnected state (OFF state).

  Next, the commercial AC voltage V <b> 1 is input to the primary winding 41 a of the insulating transformer 41. Thereby, the insulated commercial AC voltage V1 is generated in the secondary winding 41b of the insulating transformer 41, and the generated commercial AC voltage V1 is applied between the AC input terminals 2a and 2b of the inlet 2. Further, as described above, since the connection / disconnection switches 22 and 23 are in the connected state, the commercial AC voltage V1 is supplied to the supply power paths 24 and 25, the AC output terminals 3a and 3b of the outlet 3, and the power cable. It is supplied to the device under measurement 50 via the PW. At this time, as described above, since the power supply circuit 25 is selected by the ground switch 21, the power supply circuit 25 is connected to the internal ground G1 via the current limiting resistor 26 and the ammeter 28. Yes.

  In this state, the processing unit 9 executes a transformer connection detection process. In this transformer connection detection process, the processing unit 9 first executes control on the ground switch 21 when the short-circuit switch 27 is in a disconnected state as described above, thereby making the pair of supply electric circuits 24 and 25 one by one current limiting resistance. The current values I3a and I3b of the current I3 when grounded are measured by the ammeter 28.

  Specifically, as described above, since the supply circuit 25 is selected by the ground switch 21, the supply circuit 25 is connected to the internal ground G1 via the current limiting resistor 26 and the ammeter 28. ing. Therefore, in the processing unit 9, first, the CPU 9a measures the current value I3a of the current I3 flowing from the supply circuit 25 to the internal ground G1 via the current limiting resistor 26 based on the current data Di output from the ammeter 28. (Calculation), and the measured current value I3a is stored in the memory 9b in association with the supply electric path 25. Next, the CPU 9a executes a control process for the ground switch 21, and switches the ground switch 21 to the supply electric circuit 24 side. Subsequently, based on the current data Di output from the ammeter 28, the CPU 9a measures (calculates) the current value I3b of the current I3 flowing from the supply circuit 24 to the internal ground G1 via the current limiting resistor 26, and measures the current value I3b. The current value I3b is stored in the memory 9b in association with the supply electric path 24.

  Next, the CPU 9a compares the current values I3a and I3b of the measured current I3 with a predetermined threshold value Ith so that the insulation transformer 41 is connected to the AC input terminals 2a and 2b of the inlet 2. It is determined whether or not the insulation transformer 41 is connected to the polarity switching circuit 31 connected to the AC input terminals 2a and 2b.

  In this case, when the insulation transformer 41 is used and the commercial AC voltage V1 is supplied from the secondary winding 41b of the insulation transformer 41 in the floating state to the supply circuits 24 and 25 of the polarity switching circuit 31, the current limiting resistor The current value of the current I3 flowing through the circuit 26 is an extremely small value (for example, several tens of μA) when any of the supply electric circuits 24 and 25 is connected by the ground switch 21. Accordingly, the current value of the current I3 at this time is obtained by conducting an experiment or the like in advance, and the current value slightly larger than this current value is set as the threshold value Ith (for example, 1 mA). Sometimes the current values I3a and I3b of the current I3 flowing through the current limiting resistor 26 are always less than or equal to the threshold value Ith.

  On the other hand, when the insulation transformer 41 is not used and the commercial AC voltage V1 is directly supplied from the commercial power supply line to the supply power lines 24 and 25, the neutrality that configures the commercial power line of the supply power lines 24 and 25. Regarding the supply circuit to which the line is connected, when the potential generated on the neutral line is low, the current value of the current I3 (one of the current values I3a and I3b) may be less than or equal to the threshold value Ith. obtain. On the other hand, with respect to the supply electric circuit to which the live electric wire constituting the commercial power supply line of the supply electric circuits 24 and 25 is connected, the voltage of the live electric wire (high voltage such as AC100V) is applied to the current limiting resistor 26, Since the resistance value of the current limiting resistor 26 is defined in advance as described above, a current I3 having a current value of about 10 mA flows through the current limiting resistor 26. That is, when the insulating transformer 41 is not used, at least one of the current values I3a and I3b of the current I3 flowing through the current limiting resistor 26 always exceeds the threshold value Ith.

  Therefore, the CPU 9a compares the threshold value Ith stored in the memory 9b with the current values I3a and I3b of the current I3 corresponding to each of the power supply paths 24 and 25, and for any of the measured current values I3a and I3b. When the threshold value Ith or less, it is determined that the insulating transformer 41 is connected to the polarity switching circuit 31 (the insulating transformer 41 is used), and one of the measured current values I3a and I3b (current value I3a, When at least one of I3b) exceeds the threshold value Ith, it is determined that the insulating transformer 41 is not connected to the polarity switching circuit 31 (the insulating transformer 41 is not used).

  Subsequently, when the CPU 9a determines that the insulation transformer 41 is not connected as a result of the determination, the CPU 9a outputs a message to that effect to the output unit 11. In this example, since the output unit 11 is composed of a display device, the fact (for example, “insulated transformer not connected” characters) is displayed on the screen. In this case, the CPU 9a completes the transformer connection detection process and temporarily stops the operation of the leakage current measuring apparatus 1. Thereby, since the operator can grasp that the insulation transformer 41 is not connected, the supply of the commercial AC voltage V1 to the leakage current measuring device 1 is stopped and the insulation transformer 41 is connected. It becomes possible to do.

  On the other hand, when the CPU 9a determines that the insulation transformer 41 is connected as a result of the determination, the CPU 9a outputs the fact to the output unit 11 and completes the transformer connection detection process. In this example, a message to that effect (for example, “insulated transformer connected”) is displayed on the output unit 11 configured by the display device. Thereby, since the operator can grasp that the insulating transformer 41 is normally connected, the operator can recognize that the measurement process of the patient measurement current I1 can be performed.

  In the measurement processing of the patient measurement current I1, first, the operator operates the operation switches of the operation unit 10 to switch the ground switch 21 from the operation unit 10 to the processing unit 9 to the supply electric circuit 25 side. And the switching instruction | indication which makes the short circuit switch 27 transfer to a connection state is output. As a result, the processing unit 9 (specifically, the CPU 9a) inputs this switching instruction, switches the ground switch 21 to the supply electric circuit 25 side, and shifts the short-circuit switch 27 to the connected state. Therefore, the commercial AC voltage V1 is The supply circuit 25 is supplied to the device under measurement 50 with the ground potential set.

  In this state, the voltmeter 6 measures a voltage generated between predetermined parts of the measurement network 5 and outputs voltage data Dv indicating the measured voltage to the processing unit 9. In the processing unit 9, the CPU 9 a is based on the voltage (voltage generated between the predetermined parts of the measurement network 5) indicated by the input voltage data Dv and the resistance value between the predetermined parts of the measurement network 5. The patient measurement current I1 flowing between the mounting parts 51 and 52 of the device under measurement 50 is calculated (measured) and output to the output unit 11 (in this example, the patient measurement current I1 is displayed on the display device). As a result, the measurement of the patient measurement current I1 in a state where the commercial AC voltage V1 is supplied to the device under measurement 50 with the polarity that defines the supply electric circuit 25 side as the ground potential is completed.

  Next, the operator operates each operation switch of the operation unit 10 to output a switching instruction from the operation unit 10 to the processing unit 9 to switch the ground switch 21 to the supply electric circuit 24 side. Thereby, the processing unit 9 inputs this switching instruction and switches the ground switch 21 to the supply electric circuit 24 side. The secondary winding 41b side of the isolation transformer 41 is in a floating state with respect to the internal ground G1 when not connected to the internal ground G1 by the ground switch 21. For this reason, since the supply electric circuit 24 is connected to the internal ground G1 by the ground switch 21, the supply electric circuit 24 is regulated to the ground potential instead of the supply electric circuit 25, so that the supply (output) is performed between the AC output terminals 3a and 3b. ), The polarity of the commercial AC voltage V1 is reversed (the polarity is switched). At the time of switching the polarity of the commercial AC voltage V1, in the leakage current measuring apparatus 1, since neither of the supply electric circuits 24 and 25 is disconnected, the commercial AC voltage V1 is continuously supplied (the commercial AC voltage V1 Supply is not interrupted).

  In this state, the CPU 9a determines the resistance value between a voltage (voltage generated between predetermined parts of the measurement network 5) indicated by the voltage data Dv output from the voltmeter 6 and a predetermined part of the measurement network 5. Based on the above, the patient measurement current I1 flowing between the mounting parts 51 and 52 of the device under measurement 50 is calculated (measured) and output to the output unit 11 (in this example, the patient measurement current I1 is displayed on the display device) To display). Thereby, the measurement of the patient measurement current I1 is completed in a state where the commercial AC voltage V1 is supplied to the device under measurement 50 with the polarity specified on the supply electric circuit 24 side as the ground potential.

  Moreover, in this leakage current measuring apparatus 1, it is necessary to measure also the patient measurement current I1 when one of the supply electric paths 24 and 25 specified by the ground potential is in a disconnected state. Hereinafter, a procedure for measuring the patient measurement current I1 under this condition will be described. In order to execute the measurement subsequent to the measurement of the patient measurement current I1 described above, it is assumed that the supply circuit 24 side is first defined to the ground potential.

  In this state, first, the operator operates the operation switch corresponding to the connection / disconnection switch 22 in the operation unit 10 to cause the processing unit 9 to shift the connection / disconnection switch 22 to the disconnected state. A switching instruction is output. As a result, the CPU 9a controls the connection / disconnection switch 22 to shift to the disconnected state, whereby the supply electric path 24 is shifted to the disconnected state.

  Next, the CPU 9 a determines between the mounting portions 51 and 52 of the measurement target device 50 based on the voltage indicated by the voltage data Dv output from the voltmeter 6 and the resistance value between predetermined portions in the measurement network 5. Is measured (measured) and output to the output unit 11 (in this example, the patient measurement current I1 is displayed on the display device). Thereby, the measurement of the patient measurement current I1 when the supply electric circuit 24 side is regulated to the ground potential and the supply electric circuit 24 is disconnected is completed.

  Subsequently, the patient measurement current I1 is measured when the supply electric circuit 25 side is regulated to the ground potential and the supply electric circuit 25 is in a disconnected state. In this measurement, first, the operator operates each operation switch corresponding to the ground switch 21 and the connection / disconnection switches 22 and 23 in the operation unit 10, thereby causing the ground switch 21 from the operation unit 10 to the processing unit 9. Is switched to the supply electric circuit 25 side, the disconnection switch 22 is shifted to the connected state, and the switching instruction for shifting the disconnection switch 23 to the disconnected state is output. As a result, the CPU 9a controls the ground switch 21 to connect the supply circuit 25 to the ammeter 28, and also controls the connection / disconnection switch 22 to shift to the connected state, so that the supply circuit 24 shifts to the connected state. In addition, by controlling the connection / disconnection switch 23 to shift to the disconnected state, the supply electric circuit 25 is shifted to the disconnected state.

  Next, the CPU 9 a determines between the mounting portions 51 and 52 of the measurement target device 50 based on the voltage indicated by the voltage data Dv output from the voltmeter 6 and the resistance value between predetermined portions in the measurement network 5. Is measured (measured) and output to the output unit 11 (in this example, the patient measurement current I1 is displayed on the display device). Thereby, the measurement of the patient measurement current I1 when the supply electric circuit 25 side is regulated to the ground potential and the supply electric circuit 25 is disconnected is completed.

  As described above, in the leakage current measuring apparatus 1, the processing unit 9 executes control for the ground switch 21 prior to the execution of the measurement process of the leakage current (patient measurement current I1), thereby the pair of supply electric circuits 24, 25 is grounded one by one through the current limiting resistor 26 (connected to the internal ground G1) and the current values I3a and I3b of the current I3 flowing through the current limiting resistor 26 when grounded are measured by the ammeter 28. When the current values I3a and I3b are equal to or less than a predetermined threshold value Ith, it is determined that the insulating transformer 41 is connected to the supply electric paths 24 and 25 of the polarity switching circuit 31, and the measured current values I3a and I3b are determined. When at least one of I3b exceeds the threshold value Ith, it is determined that the insulating transformer 41 is not connected to the supply electric circuits 24 and 25 of the polarity switching circuit 31. Executing a transformer connection detection process that.

  Therefore, according to this leakage current measuring apparatus 1, it is possible to reliably determine whether or not the insulating transformer 41 is connected to the polarity switching circuit 31 by the transformer connection detection process. The measurement process of the leakage current (patient measurement current I1) performed while switching the polarity of the AC voltage V1 can be executed while reliably avoiding the interruption of the commercial AC line (interruption of the supply of the commercial AC voltage V1) by the leakage breaker. it can.

  Further, according to the leakage current measuring apparatus 1, when the processing unit 9 determines that the insulating transformer 41 is not connected to the polarity switching circuit 31 in the transformer connection detection processing, the fact is output to the output unit 11. Thus, the operator can surely and easily grasp that the insulating transformer 41 is not connected.

  The above leakage current measuring apparatus 1 employs a configuration in which the ground switch 21, the current limiting resistor 26, the shorting switch 27, and the ammeter 28 are used one by one, but the leakage current measuring apparatus 1A shown in FIG. As shown, the parallel circuit of the current limiting resistor 26a and the short-circuit switch 27a, the ground switch 21a and the ammeter 28a are connected in series, connected between the supply circuit 24 and the internal ground G1, and the current limiting resistor 26b and A configuration in which the parallel circuit of the short-circuit switch 27b, the ground switch 21b, and the ammeter 28b are connected in series and connected between the supply electric circuit 24 and the internal ground G1 may be employed.

  In this leakage current measuring apparatus 1A, single-pole single-throw switches (relays) are used as the ground switches 21a and 21b, and the two ground switches 21a and 21b and the two short-circuit switches 27a and 27b are controlled. By doing so, each end part (supply electric circuit 24, 25) of the secondary winding 41b is selectively connected (grounded) to the internal ground G1. In addition, the polarity switching circuit 31A is configured by supply electric circuits 24 and 25, ground switches 21a and 21b, ammeters 28a and 28b, current limiting resistors 26a and 26b, and short-circuit switches 27a and 27b. In addition, about the structure same as the leakage current measuring apparatus 1, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  In this configuration, the CPU 9a controls each end of the secondary winding 41b by controlling the two ground switches 21a and 21b to be connected one by one in the state where the two short-circuit switches 27a and 27b are controlled to be disconnected. (Supply electric lines 24 and 25) are selectively connected to the internal ground G1 with a corresponding current limiting resistor 26a (or current limiting resistor 26b) interposed therebetween. Further, when the supply circuit 24 is connected to the internal ground G1 with the current limiting resistor 26a interposed, the CPU 9a has a current I31 flowing through the current limiting resistor 26a based on the current data Dia output from the ammeter 28a. When the value I3a is measured and the supply circuit 25 is connected to the internal ground G1 with the current limiting resistor 26b interposed, the current I32 flowing through the current limiting resistor 26b based on the current data Div output from the ammeter 28b. The current value I3b is measured, and each current value I3a, I3b is compared with the threshold value Ith. Further, as a result of this comparison, the CPU 9a determines that the insulating transformer 41 is connected to the polarity switching circuit 31A when any of the measured current values I3a and I3b is equal to or less than a predetermined threshold value Ith. When at least one of the measured current values I3a and I3b exceeds the threshold value Ith, it is determined that the insulating transformer 41 is not connected to the polarity switching circuit 31A.

  With this configuration, even in the leakage current measuring apparatus 1A, it is possible to reliably determine whether or not the insulation transformer 41 is connected and output the output to the output unit 11. Therefore, the polarity of the commercial AC voltage V1 with respect to the device under measurement 50 can be changed. The measurement process of the leakage current (patient measurement current I1) performed while switching can be executed while reliably avoiding the interruption of the commercial AC line (interruption of the supply of the commercial AC voltage V1) by the earth leakage breaker.

  Note that the leakage current measuring device 1 that measures the patient measurement current I1 as an example of the leakage current has been described above. However, the simulation circuit 4 in the leakage current measurement device 1 has a leakage current other than the patient measurement current I1, a ground leakage current (measured) A leakage current that flows from the protective ground PE of the target device 50 to the ground via the ground terminal 2c of the inlet 2, and the measurement network 5 is connected between the ground terminal 3c of the outlet 3 and the ground terminal 2c of the inlet 2. Of course, the present invention can be applied to a leakage current measuring device that measures a current measured by measuring a voltage value of a voltage generated between both ends of the measurement network 5. Moreover, although the leakage current measuring apparatus 1 and 1A provided with the measurement network 5 inside was demonstrated, of course, the measurement network 5 may be a different body from the leakage current measuring apparatus.

DESCRIPTION OF SYMBOLS 1,1A Leakage current measuring apparatus 4 Simulated circuit 5 Measurement network 6 Voltmeter 9 Processing part 2a, 2b AC input terminal 3a, 3b AC output terminal 21 Ground switch 22, 23 Connection switch 26 Current limiting resistor 27 Short circuit switch 28 Ammeter 31, 31A Polarity switching circuit 41 Insulating transformer 41a Primary winding 41b Secondary winding 50 Device to be measured I3a, I3b Current value Ith threshold value V1 Commercial AC voltage

Claims (2)

Measure the voltage between both ends of a simulation circuit including a polarity switching circuit that switches the polarity of the input commercial AC voltage and supplies it to the device under measurement, and the measurement network that constitutes the leakage current path for the device under measurement. A voltmeter and a processing unit;
The polarity switching circuit is connected to both ends of a secondary winding of an insulating transformer in which the commercial AC voltage is input to the primary winding, and the insulated commercial AC voltage output from the secondary winding is supplied to the polarity switching circuit. A pair of supply circuits that are input and supplied to the device to be measured, a current limiting resistor, and an arbitrary one of the pair of supply circuits connected in series with the current limiting resistor. A grounding switch that is selectively grounded via the current limiting resistor, a shorting switch that is connected in parallel to the current limiting resistor and configured to be able to short-circuit the current limiting resistor, and an ammeter that detects a current flowing through the grounding switch And configured with
The processing unit performs control on the ground switch when the short-circuit switch is in a disconnected state, thereby grounding the pair of supply electric circuits one by one via the current limiting resistor and the current when the ground switch is grounded. The current value is measured with the ammeter, and when any of the measured current values is equal to or less than a predetermined threshold value, it is determined that the insulation transformer is connected to the polarity switching circuit. A leakage current measuring device that performs a transformer connection detection process for determining that the insulating transformer is not connected to the polarity switching circuit when at least one of the measured current values exceeds the threshold value.   The leakage current measuring device according to claim 1, wherein when the processing unit determines that the insulating transformer is not connected in the transformer connection detection processing, the processing unit outputs a message to that effect to the output unit.

Images